Order type

File:Magnetic rope.svg

Plasma parameters define various characteristics of a plasma, an electrically conductive collection of charged particles that responds collectively to electromagnetic forces. Plasma typically takes the form of neutral gas-like clouds or charged ion beams, but may also include dust and grains. ^[1] The behaviour of such particle systems can be studied statistically. ^[2]

Fundamental plasma parameters

All quantities are in Gaussian (cgs) units except temperature expressed in eV and ion mass expressed in units of the proton mass ${\displaystyle \mu =m_i/m_p}$; Z is charge state; k is Boltzmann's constant; K is wavenumber; γ is the adiabatic index; ln Λ is the Coulomb logarithm.

Frequencies

• electron gyrofrequency, the angular frequency of the circular motion of an electron in the plane perpendicular to the magnetic field:

${\displaystyle {\omega }_{ce}=eB/m_{e}c=1.76\times 10^{7}B\text{rad/s}}$

• ion gyrofrequency, the angular frequency of the circular motion of an ion in the plane perpendicular to the magnetic field:

${\displaystyle {\omega }_{ci}=eB/m_{i}c=9.58\times 10^{3}Z{\mu }^{-1}B\text{rad/s}}$

• electron plasma frequency, the frequency with which electrons oscillate (plasma oscillation):

${\displaystyle {\omega }_{pe}=(4\pi n_e{e}^2/m_e{)}^{1/2}=5.64\times 10^4{n}_e^{1/2}\text{rad/s}}$

• ion plasma frequency:

${\displaystyle {\omega }_{pi}=(4\pi n_i{Z}^2{e}^2/m_i{)}^{1/2}=1.32\times 10^{3}Z{\mu }^{-1/2}{n}_i^{1/2}\text{rad/s}}$

• electron trapping rate:

${\displaystyle {\nu }_{Te}=(eKE/m_e{)}^{1/2}=7.26\times 10^8{K}^{1/2}{E}^{1/2}{\text{s}}^{-1}}$

• ion trapping rate:

${\displaystyle {\nu }_{Ti}=(ZeKE/m_i{)}^{1/2}=1.69\times 10^7{Z}^{1/2}{K}^{1/2}{E}^{1/2}{\mu }^{-1/2}{\text{s}}^{-1}}$

• electron collision rate:

${\displaystyle {\nu }_e=2.91\times 10^{-6}{n}_e\ln \mathrm{\Lambda }{T}_e^{-3/2}{\text{s}}^{-1}}$

• ion collision rate:

${\displaystyle {\nu }_i=4.80\times 10^{-8}{Z}^4{\mu }^{-1/2}{n}_i\ln \mathrm{\Lambda }{T}_i^{-3/2}{\text{s}}^{-1}}$

Lengths

• Electron thermal de Broglie wavelength, approximate average de Broglie wavelength of electrons in a plasma:

${\displaystyle {\mathrm{\Lambda }}_e=\sqrt{\frac{h^2}{2\pi m_{e}k{T}_e}}=6.919\times 10^{-8}{T}_e^{-1/2}\text{cm}}$

• classical distance of closest approach, the closest that two particles with the elementary charge come to each other if they approach head-on and each have a velocity typical of the temperature, ignoring quantum-mechanical effects:

${\displaystyle e^2/kT=1.44\times 10^{-7}{T}^{-1}\text{cm}}$

• electron gyroradius, the radius of the circular motion of an electron in the plane perpendicular to the magnetic field:

${\displaystyle r_e=v_{Te}/{\omega }_{ce}=2.38T_e^{1/2}{B}^{-1}\text{cm}}$

• ion gyroradius, the radius of the circular motion of an ion in the plane perpendicular to the magnetic field:

${\displaystyle r_i=v_{Ti}/{\omega }_{ci}=1.02\times 10^2{\mu }^{1/2}{Z}^{-1}{T}_i^{1/2}{B}^{-1}\text{cm}}$

• plasma skin depth, the depth in a plasma to which electromagnetic radiation can penetrate:

${\displaystyle c/{\omega }_{pe}=5.31\times 10^5{n}_e^{-1/2}\text{cm}}$

• Debye length, the scale over which electric fields are screened out by a redistribution of the electrons:

${\displaystyle {\lambda }_D=(kT/4\pi n{e}^2{)}^{1/2}=7.43\times 10^2{T}^{1/2}{n}^{-1/2}\text{cm}}$

• Ion inertial length, the scale at which ions decouple from electrons and the magnetic field becomes frozen into the electron fluid rather than the bulk plasma:

${\displaystyle d_i=c/{\omega }_{pi}}$

Velocities

• electron thermal velocity, typical velocity of an electron in a Maxwell-Boltzmann distribution:

${\displaystyle v_{Te}=(k{T}_e/m_e{)}^{1/2}=4.19\times 10^7{T}_e^{1/2}\text{cm/s}}$

• ion thermal velocity, typical velocity of an ion in a Maxwell-Boltzmann distribution:

${\displaystyle v_{Ti}=(k{T}_i/m_i{)}^{1/2}=9.79\times 10^5{\mu }^{-1/2}{T}_i^{1/2}\text{cm/s}}$

• ion sound velocity, the speed of the longitudinal waves resulting from the mass of the ions and the pressure of the electrons:

${\displaystyle c_s=(\gamma Zk{T}_e/m_i{)}^{1/2}=9.79\times 10^5(\gamma Z{T}_e/\mu {)}^{1/2}\text{cm/s}}$

• Alfvén velocity, the speed of the waves resulting from the mass of the ions and the restoring force of the magnetic field:

${\displaystyle v_A=B/(4\pi n_i{m}_i{)}^{1/2}=2.18\times 10^{11}{\mu }^{-1/2}{n}_i^{-1/2}B\text{cm/s}}$

Dimensionless

File:Fusor running.jpg

• square root of electron/proton mass ratio

${\displaystyle (m_e/m_p{)}^{1/2}=2.33\times 10^{-2}=1/42.9}$

• number of particles in a Debye sphere

${\displaystyle (4\pi /3)n{\lambda }_D^3=1.72\times 10^9{T}^{3/2}{n}^{-1/2}}$

• Alfvén velocity/speed of light

${\displaystyle v_A/c=7.28{\mu }^{-1/2}{n}_i^{-1/2}B}$

• electron plasma/gyrofrequency ratio

${\displaystyle {\omega }_{pe}/{\omega }_{ce}=3.21\times 10^{-3}{n}_e^{1/2}{B}^{-1}}$

• ion plasma/gyrofrequency ratio

${\displaystyle {\omega }_{pi}/{\omega }_{ci}=0.137{\mu }^{1/2}{n}_i^{1/2}{B}^{-1}}$

• thermal/magnetic pressure ratio ("beta")

${\displaystyle \beta =8\pi nkT/B^2=4.03\times 10^{-11}nT{B}^{-2}}$

• magnetic/ion rest energy ratio

${\displaystyle B^2/8\pi n_i{m}_i{c}^2=26.5{\mu }^{-1}{n}_i^{-1}{B}^2}$

See also

• List of plasma (physics) articles

References

• NRL Plasma Formulary (esp. p. 28 and p. 29), J.D. Huba, Naval Research Laboratory (2007)

Footnotes